Document 6430177
Transcription
Document 6430177
Gen Physiol Biophys (1997), 16, 321—327 321 P o t e n t i a l Cancerostatic Benfluron is Metabolized by Peroxidase: In vitro Biotransformation of Benfluron by Horseradish Peroxidase K HRUBÝ, E ANZENBACHEROVÁ, P A N Z E N B A C H E R AND M NOBILIS Institute of Experimental Biopharmaceutics, PRO MED CS Praha & Academy of Sciences, Hradec Králové, Czech Republic A b s t r a c t . Horseradish peroxidase (HRP) was used to investigate whether ben fluron (a potential cytostatic drug) can be biotransformed extra-hepatically by systems other than flavin-containing monooxygenase and cytochromes P450 Three types of incubation mixtures differrmg in buffers (Na-phosphate buffer 50 mmol/1, pH 6 8 and 8 4 and Tris-HCl buffer 25 mmol/1, pH 7 5) were tested The amount of N-demethylated benfluron (demB) formed was significantly higher (up to 4 times in the Na-phosphate buffer, pH 8 4, and 5 times in the Na-phosphate buffer, pH 6 8, and in the Tris-HCl buffer, pH 7 5) compared to control experiments The highest yields of demB were obtained with the modeiately alkaline Na-phosphate buffer (50 mmol/1, pH 8 4) The concentiation of demB increased during thirty minutes of incubation, and then remained constant through the end of two-hour incubation The íesults support the hypothesis that benfluron can be metabolized extra-hepatically by N-demethylation reaction catalyzed by peroxidases Key words: Horseradish peroxidase — Dealkylation — Neoplasms — Benfluron — Cytochrome P-450 Introduction Benfluron (5-(2-dimethylaminoethoxy)-7H-benzo[c]fluorene hydrochloride) is a pro spective cancerostatic agent (Mélka and Kfepelka 1987), the biological effects, biodistnbution and biotransformation of which have been investigated in depth both vivo and in vitro (Kvasničková et al 1984, Francová et al 1985, Nobilis et al 1991) The metabolites of benfluron have been identified (Fig 1), and enzyme systems involved in benfluron biotransformation have also been investigated (KvasCorrespondence to Pavel Anzenbacher, D Sc , Institute of Experimental Biopharma ceutics, PRO MED CS Praha & Academy of Sciences, Heyrovskehol207, 500 02 Hradec Králové, Czech Republic E-mail uebf@hk cesnet cz Hrubý et al. 322 ničková et al. 1984). The purpose of our study was to look at whether enzymes other than flavin-containing monooxygenase (FMO) and cytochrome P450 (P450) could also be involved in benfluron biotransformation. t t f Figure 1. In vitro metabolic pathways of benfluron. 10 - benfluron; 9 - N-demethylated benfluron; 8 - reduced benfluron, 7 - 9-hydroxybenfluron; 6 - reduced N-demethylated benfluron, 5 - 5,9-dihydroxy-7-oxo-7H-benzo[c]fluorene; 4 - benfluron N-oxide; 3 - re duced 9-hydroxybenfluron, 2 - reduced benfluron N-oxide; 1 - 5,7,9-trihydroxy-7H-benzo [c]fluorene. Peroxidases (EC 1.11.1.7), abundant in plants as well as in animals, are known to be able to participate in biotransformation of many compounds (Guengerich 1990; Stiborová et al. 1991). For example, prostaglandin H synthase (PGHS) (EC 1.14.99.1) which converts arachidonic acid to cyclic endoperoxide/hydroperoxide prostaglandin G 2 (PgG 2 ) is localized in the urinary bladder epithelium and in the kidney, prostate or in the colon mucosa in man. PGHS is known to oxidize many carcinogens such as 2-aminofluorene, 2-naphthylamine or benzidine (Guengerich 1990). Hence, this enzyme may contribute to the development of fatal colon cancers; Metabolism of Benfluron by Peroxidase 323 the use of aspirin, an inhibitor of PGHS, is associated with a reduced risk of this disease (Thun et al 1991) Horseradish peroxidase (HRP) is often used as a tool for modeling extrahepatic biotransformation of xenobiotics (Josephy et al 1983a,b, Ross et al 1985, Sugiyama et al 1994) It possesses heme b (a fernprotoporphyrm IX) as the prosthetic group, and nitrogen atom from a histidme residue as the heme iron proximal hgand (Meunier 1987) We used HRP as a model peroxidase to investigate its ability to catalyze (in the presence of hydrogen peroxide) the conversion of benfluron to known metabolites Materials and M e t h o d s Chemicals Benfluron was a generous gift from Reseaich Institute of Pharmacy and Biochemistry m Prague (Czech Republic) HRP (type II) was puichased from Sigma (St Louis, USA) Acetomtnle was purchased from Merck (Darmstadt, Geimany), and nonylamine was from Fluka (Buchs, Switzerland) All other chemicals were from Lachema (Brno, Czech Republic), and were of analytical-grade purity Incubation and extraction procedures Incubation mixture contained HRP (2 0 mg), hydrogen peroxide (1 5 mmol/1), benfluron (0 2 mmol/1) Three types of buffers were used Na-phosphate buffer (50 mmol/1, pH 6 8 and 8 4) and Tris-HCl buffer (25 mmol/1, pH 7 5) Total volume of incubation (mixture) was 1 5 ml Samples were premcubated 5 minutes at 37°C, then HRP was added, and the reaction mixture was incubated for 120 minutes at 37 °C Incubations were done in triplicate Control incubations without HRP were made simultaneously For the time experiment, the reaction mixture was mcubated for 1, 3, 5, 15, 30, 60, and 120 minutes Incubation was stopped by addition of 5 ml 5% (v/v) ammonium hydroxide and cooling The samples were extracted three times with 8 ml of ethylacetate each Extracts were collected and ethylacetate was evapoiated under vacuum at 40°C The residue was dissolved in a small volume of methanol, the solvent was then evaporated by a stream of nitrogen at 50°, and the samples were stored for HPLC HPLC Samples were analyzed on a reverse-phase Cis column (5 /xm, 125 x 4 mm) (Merck) with a system consisting of AS3500 autosampler and P4000 ternary pump (Thermo Separation Products) Analyses were done under isocratic conditions with a mobile phase consisting of 40% nonylamine buffer pH 7 41 40% acetomtnle 20% isopropanol at the rate of 0 90 ml/min HPLC profile was monitored at 295 and Hrubý et al 324 340 nm using Spectra FOCUS foiward optical scanning detectoi (TSP) Metabolites weie quantified by comparing their peak areas with peak areas of external standaids This procedure was done using Spectra SYSTEM™ software PC1000 (TSP) Metabolites were identified by then known retention times and by their chaiactenstic spectia taken by the detector 300 250 200 > E c o 150 Q. (A <D 100 15 20 Time (min) Figure 2. HPLC elution piofile of benfluron incubation with HRP Peak A, benfluron Noxide peak B 9-hydroxvbenfluron, peak C, N-demethylated benfluron, peak D, benfluron, peak X, unidentified metabolite Thick hne, absorbance at 295 nm, dotted line absorbance at 340 nm Results and Discussion HPLC piofiles of benfluron and its metabolites aie shown in Fig 2 Retention times of peaks A, B, C, D were in accordance with the retention times of known standards Peak A was identified as benfluion N-oxide (N-oxB), peak B as 9-hydroxybenfluron (9-OHB), peak C as N-demethylated benfluron (demB), and peak D as benfluron Fuithermore, peak X was detected in extracts from HRP incubations and control incubations Its retention time did not correspond to retention time of any known metabolite Metabolism of Benfluron by Peroxidase 325 Table 1. Effect of various buffers on the concentrations of benfluron metabolites from incubations with HRP* and from control incubations Concentration [nmol/ml] Metabolite Na-phosphate buffer 50 mmol/1, pH 8 4 Control N-oxB 60 50 ± 13 03 99 15 ± 3 41 9-OHB + demB 0 73 ± 0 20 6 74 ± 1 37 0 87 ± 0 13 1 83 ± 0 46 Na-phosphate buffer 50 mmol/1, pH 6 8 Control 53 51 ± 13 13 0 81 ± 0 25 2 99 ± 0 84 0 71 ± 0 07 134 69 ± 9 23 nd* Tris-HCl buffer 25 mmol/1, pH 7 5 Control 52 84 ± 8 85 108 14 ± 18 67 1 49 ± 0 38 3 59 ± 1 74 nd 0 80 ± 0 19 "Abbreviations used HRP, horseradish peroxidase, N-oxB, benfluron N-oxide 9-OHB, 9-hydroxybenfluion, demB, N-demethylated benfluron Values are means ± S D for three experiments ' n d not detected Concentration of demB was significantly mcieased compaied with contiol ex periment The concentrations of identified metabolites are shown in Table 1 The íesults show a significant increase of N-demethylated product formation compared to control expenments On the other hand, yields of N-oxB are significantly dimin ished in the presence of HRP This reaction is known to take place spontaneously benfluron in solutions slowly oxidizes to form this compound Also, anothei metabo lite, 9-OHB, was formed However, its yields were relatively low The results show that this product could also be foimed in the absence of HRP in alkaline pH (Table 1) Na-phosphate buffer (pH 8 4) was selected as a medium to study the kinetics of demB formation The results are shown in Fig 3 DemB already occurred after piemcubation This is in agreement with the results shown in Table 1 spontaneous foimation of demB m the presence of hydrogen peroxide could be an explanation Neveitheless, there was a significant mciease in demB concentiation during thirty minutes of incubation with HRP Theieafter, demB concentration remained con stant throughout the end of two-hour incubation The metabolism of benfluron has recently been extensively studied FMOs are known to be involved in benfluron biotransformation yielding an N-oxide, and that hydroxylation and N-demethylation are catalyzed by P450 (Kvasničková et al 1984) The results of a biodistnbution study (Francová et al 1985) indicated that benfluion could also be a substrate foi extra-hepatic biotransformation catalyzed by different systems Among them, the peroxidases occurring e g m the uimary bladder, in the mammary gland, eosinophiles, leukocytes, the uterus or in pul- Hrubý et al. 326 60 80 Time (min) Figure 3. Formation of N-demethylated benfluron over time. The results shown are means from five experiments. monary and renal cells (Stiborová et al. 1991) may play a significant role. We used HRP to model extrahepatic biotransformation by peroxidases. This approach has been widely used (Josephy et al. 1983a,b; Sugiyama et al. 1994; Ross et al. 1985; Meunier 1987; Guengerich 1990). Our results clearly show that HRP catalyzed Ndemethylation of benfluron as the amounts of demB were significantly increased in the presence of this hemoprotein. It is known that HRP is able to catalyze Ndemethylation reactions as well as P450; the reaction mechanisms, however, are most probably diffferent (Okazaki and Guengerich 1993; Anzenbacher et al. 1996). This property seems to be typical of all heme-containing systems (hemoproteins as well as the model ones). The results show that benfluron could be metabolized by N-demethylation reaction mediated by peroxidases. This fact adds new piece of evidence to suggestions on the importance of extra-hepatic biotransformations and the role of peroxidases in these processes. Acknowledgements. Work on this project was partly covered by grants No. 784103 from Grant Agency of the Academy of Sciences of the Czech Republic, and No. 203/96/017 from Grant Agency of the Czech Republic. 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